DE10029585C2 - Method for operating a magnetic resonance device with detection of changes in position - Google Patents

Abstract

A method for operating a magnetic resonance device includes the following features: DOLLAR A - With a first examination of an examination object, a first scout image data record of the examination object is generated, with respect to which at least one first slice of the examination object to be imaged is defined, DOLLAR A - with at least one further one After the first examination of the examination object following in time, a further scout image data record of the examination object is generated, DOLLAR A - a change in position is determined between the first and the further scout image data set, and DOLLAR A - at least one further layer of the examination object to be imaged is determined in accordance with the determined change in position, which has the same positioning within the examination object with respect to the first layer.

Description

The invention relates to a method for operating a mag netresonanzgeräts.

Magnetic resonance technology is a known technique for ge obtaining images of the inside of an examination object jekts. In this case, a stati basic magnetic field quickly switched gradient fields superimposed, which are generated by a gradient system. Furthermore, the magnetic resonance device comprises a radio frequency system tem, which for triggering magnetic resonance signals Hochfre radiates frequency signals into the object under examination and the generates generated magnetic resonance signals on the basis thereof Image data sets and magnetic resonance images are created.

In functional magnetic resonance imaging, a same area of an examination object to be imaged Image data records were recorded in a chronological sequence. Here are used to filter out differences between the Image data sets, the result of a change in the position of the image the area related to the device during the temporal Sequences are known, corresponding methods.

A group of methods for determining the change in position from temporally successively recorded image data sets is based on a description of any rigid body movement in three-dimensional space by means of six movement parameters, three parameters characterizing translations and three parameter rotations. The aforementioned parameters are noted, for example, in a column vector. The values of all voxels or selected voxels of a first image data set and a second image data set, which was generated temporally following the first, are noted in a corresponding order in a first column vector and a second column vector. To determine a change in position between the recording times of the first and second image data sets, ie to determine the movement parameters, the following equation, which is based on a Taylor order of the first order, is solved, for example, by an iterative process:

For a more precise description of location based on image data records change detection algorithms of the aforementioned group for example on the book by R.S.J. Frackowiak et al., "Human Brain Function", Academic Press, 1997, in particular Chapter 3, pages 43 to 58 and on the article by K.J. Friston et al., "Movement-Related Effects in fMRI Time- Series ", Magnetic Resonance in Medicine 35 (1996), pages 346 referred to 355.

Another group of methods for image data sets based position change detection are all or certain te selected points of a first described in k-space Image data set and a second image data set, which the first ten was subsequently generated with each other compared. The procedures are based on the fact that as a result of a change in position between the time of recording of both image data sets when compared from within data points arranged in the same way in both image data sets Translations and / or rotations of the area to be imaged in a change in phase and / or amount of data point reflect. Embodiments of the aforementioned method are for example in the article by L.C. Maas et al., "De coupled Automated Rotational and Translational Registration for Functional MRI Time Series Data: The DART Registration Algorithms ", Magnetic Resonance in Medicine 37 (1997), pages 131 to 139 and in the article by Q. Chen et al., "Symmetric  Phase-Only Matched Filtering of Fourier-Mellin Transforms for Image Registration and Recognition ", IEEE Transactions on Pattern Analysis and Machine Intelligence, Vol. 16, No. 12 (1994), pages 1156 to 1168.

EP 0 909 958 A2 describes the generation of a so-called animated magnetic resonance image in which different Parts of the magnetic resonance image are sequentially staggered be measured again, and an updated Magnetre sonanzbild is reconstructed using an echoplanar technique wrote. Each high-frequency pulse is associated with one gene echo planar sequence subsequently generated a navigator echo and recorded. The navigator echoes become hermits Determine and correct movements of an image to be imaged richly used during imaging. For this, Navigator echoes with a previous one, use as reference compared navigator echo in k-space, depending on speed of the newly measured part of the magnetic resonance image in each case a correspondingly different navigator echo is used as a reference becomes.

As part of a follow-up, it is common to get one controlling area of an examination object several times by successive and spaced apart from each other Examinations with a magnetic resonance device correspond to map accordingly. The examinations take place at for example, every few hours or weeks. An operator tries the magnetic resonance device after a first examination following examination by manual input the exam positioning object in the device and the device so that the images to be recorded are related positioning within the examination object possible correspond to those of the first examination. by virtue of manual setting only becomes moderate Agreement reached. Furthermore, there is a degree of agreement  depends on the operator. Furthermore, it is featured called manual adjustment comparatively time consuming.

Magnetic resonance technology is used in the usual language a basic or overview magnetic resonance image that serves as a template serves for a graphic positioning of layers, as Called Scout. For example, in US 5,323,111 a first magnetic resonance displayed on a screen image, on the basis of which line cursors are used to display more end layers are selected as a scout. Fer ner is in the book by S.S. Rajan "MRI. A Conceptual Over view ", Springer-Verlag, 1998, pages 76-78 described that the selection of layers to be imaged by a graphi cursors placed in scout images becomes. The scout images are magnetic resonance images that along one or more orientation around an isocenter of a basic field magnet, usually with a gra service technology can be quickly adopted. Furthermore is from DE 198 05 112 A1 in front of an actual image known to carry out a scout for which Cross-sectional images in axial, coronal and sagittal orientia tion exactly through a center and through a basic field mag neten and a gradient coil system specific magnetic resonance nance coordinate system are generated continuously.

The object of the present invention is to provide a method for Operation of a magnetic resonance device to create the under others mentioned in the course of a follow-up inspection Disadvantages reduced.

The object is achieved by the subject of Claim 1 solved. Advantageous configurations are in the Subclaims described.

A method for operating a magnetic resonance device according to claim 1 includes the following features:

• - During a first examination of an object under examination becomes a first scout image data record of the examination object tes generated, with respect to the at least a first image the slice of the examination object is determined,
• - in the case of at least one further, the first one in time A thorough examination of the object under investigation is carried out tere scout image data record of the examination object testifies,
• - between the first and the further Scout image data record a change in position is determined and
• - According to the determined change in position, little will be done at least one further layer of the examination object to be imaged jektes determines the one with respect to the first layer same positioning within the examination object having.

This ensures that the magnetic resonance device at further examination automatically, highly precisely and in time-effi is set so that the other Examination of magnetic resonance images to be generated with regard to positioning within the object under investigation exactly match those of the first examination. Thereby maximum comparability of the magnetic resonance images. Differences between magnetic resonance images of the first and further investigation due to an inaccurate setting in the further investigation are excluded, so that for example pathological changes as such are clearly diagnosable.

In an advantageous embodiment, the Change in position the procedure for Determination of changes in position from image data sets on the basis a first order Taylor development.

In an advantageous embodiment, the scout Image data sets as three-dimensional image data sets, in particular others with a quick image technique, for example an E choplanar method. This makes any rotations  and / or translations in three-dimensional space as La Ge changes can be determined from the Scout image data sets. Furthermore, the scout image data sets are time efficient received.  

In an advantageous embodiment, the examination object in the further investigation accordingly for the first examination of stored data automatically in the magnet resonance device positioned. In a first step guidance of the examination object during the further examination according to the first examination on a storage device direction of the device. In a patient this means for example, that according to the first investigation stored on his back and head first. After that becomes a method of the positioning device for positioning of the area of the object to be imaged in the figure volume of the device based on the data for the first examination stored data automatically and without one Stopover, for example under one of the images to be depicted Area marking laser sight. In one the patient will carry them out during the further examination in the scope of the given options the storage device stored. A camera captures it system the outline of the patient depending on his Mounting. In connection with the saved data of The first examination turns it into a storage procedure device determined and carried out so that the white Further examination of the same area of the patient to be imaged position in the image volume, as with the first th investigation.

Further advantages, features and details of the invention result from the following description of an embodiment Example based on the drawing.

The figure shows, as an exemplary embodiment of the invention, a flow chart for a progress control using magnetic resonance images. The course check begins with a first examination 10 at a first point in time. After positioning, for example, an abdominal area of a patient to be imaged in the imaging volume of a magnetic resonance device, a first scout data record of the area to be imaged is generated in step 11 . On the basis of this first scout data record, diagnostically meaningful layers are determined in step 12 by a diagnosing doctor. Finally, magnetic resonance images are recorded in a step 13 in accordance with the defined layers.

After a few days, the same area of the same patient to be imaged is examined again to check the success of the treatment. For this purpose, the same area to be imaged is positioned in the imaging volume of the device in a further examination 20 . In this case, positioning that is completely identical with respect to the first examination 10 already fails because the patient cannot be positioned with millimeter accuracy on a positioning device of the device. After positioning, a further scout data record 21 is generated as part of the further investigation 20 . In a step 22 , the further scout data record is compared with the first scout data record in a control system of the device. To do this, the control system uses one of the methods already described at the beginning. In step 23 , based on the change in position determined in step 22, layers to be imaged are defined such that the layers of the further examination 20 correspond to the layers of the first examination 10 with regard to positioning within the patient. Finally, in step 24, a corresponding de magnetic resonance imaging of the slices defined in step 23 takes place. Differences between a magnetic resonance image of the first examination 10 and a magnetic resonance image of the second examination 20 for the same slice are direct indications of a positive or negative treatment success for the diagnosing doctor. Differences as a result of non-congruent layers between the first examination 10 and the second examination 20 as well as misinterpretations resulting therefrom are certainly excluded.

Claims (6)

1. Method for operating a magnetic resonance device, including the following features:
During a first examination of an examination object, a first scout image data record of the examination object is generated, with respect to which at least one first layer of the examination object to be imaged is defined,
in the case of at least one further examination of the examination object following the first time, a further scout image data record of the examination object is generated,
A change in position is determined between the first and the further Scout image data record
In accordance with the determined change in position, at least one further layer of the examination object to be imaged is determined, which has the same positioning within the examination object with respect to the first layer. 2. The method according to claim 1, wherein determining the change in position includes the following features:
At least selected values of the first scout image data set are noted in a first vector,
according to the selected values of the first scout image data set, values of the second scout image data set are selected and noted in a second vector,
In a third vector, six parameters are noted with which any change in position in three-dimensional space can be described,
According to a first-order Taylor development, an equation is formed in which a difference between the second and the first vector is set equal to a product of a Jacobian functional matrix with the third vector, the Jacobian functional matrix per line being partial derivatives of the corresponding value of the first vector after the six parameters, and
the equation for determining the six parameters is solved by an iteration process. 3. The method according to any one of claims 1 or 2, wherein the Scout image data sets as three-dimensional image data sets be fathered. 4. The method according to any one of claims 1 to 3, wherein the Scout image data sets generated with a quick image technique become. 5. The method according to any one of claims 1 to 4, wherein the Scout image data sets generated with an echoplanar process become. 6. The method according to any one of claims 1 to 5, wherein the The object to be examined during the further examination corresponds automatically stored data for the first examination table is positioned in the magnetic resonance device.